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Publication numberUS2178953 A
Publication typeGrant
Publication dateNov 7, 1939
Filing dateOct 16, 1937
Priority dateOct 16, 1937
Publication numberUS 2178953 A, US 2178953A, US-A-2178953, US2178953 A, US2178953A
InventorsRoland Chilton
Original AssigneeWright Aeronautical Corp
Export CitationBiBTeX, EndNote, RefMan
External Links: USPTO, USPTO Assignment, Espacenet
Hydraulic plunger seal
US 2178953 A
Abstract  available in
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Claims  available in
Description  (OCR text may contain errors)

Nov. 7, 1939. R. CHILTON HYDRAULIC PLUNGER SEAL Filed Oct. 16, 1957 Illll 1 N VE N TOR. KOLHND Mara/v ATTORNEY.

Patented Nov. 7, 1939 UNITED STATES PATENT OFFICE HYDRAULIC PLUNGER SEAL Roland Chilton, Ridgewood, N. J., assignor to Wright Aeronautical Corporation, a corporation of New York Application October 16, 1937, Serial No. 169,350 4 Claims. (01(137-157) in the art and comprise a flexible sleeve, usually of rubber, having inner and outer cylindrical parts so that the inner part may move relatively to the outer, part by a rolling action, whereby material is paid off around the joining element from the inner to the outer parts in one direction of movement and vice versa in the other, as in the process of turning a stocking" inside out.

The prime feature of the present invention consists in a. special method of reinforcing the seal member by flexible cords having a novel disposition whereby elastic stretch of the rubber element under fluid pressure is prevented without in any way impairing the ability of the flexible material to roll in operation to transfer itself from theinner and outer circumferences.

Other objects will be obvious from, or will be pointed out in the following description, with reference to the drawing, in which:

Fig. 1 is an axial section of a cylinder-plunger incorporating a seal;

Fig. 2 is a transverse section on the line 2-2 of Fig. 1;

Fig. 3 is a developmentof the seal alone;

' Fig. 4 is a development of an alternative seal, and

Fig. 5 is an axial section through a cylinderplunger incorporating'the seal of Fig. 4.

In the drawing, I0 designates a cylinder element in which is slidably fitted a plunger l2 having a projecting head l4 of reduced diameter. A flexible seal l5 between the cylinder l0 and the head I4 comprises a bead IS, an outer tubular portion l8 and an inner tubular portion 20, joined by the rolled portion 22, a head portion 24 completing the seal and overlapping the head l4. The seal l5 comprises a flexible diaphragm bridging the head I4 and the cylinder Ill and allowing movement therebetween.

Reinforcing cords 26 extend from the head it through the wall portions |8--20-22 across the head 24 downthe diametrically opposite wall portions back up to the head It. Within this bead the cords may be wrapped around a form ring 25 and the entire reinforcement may be laid up from a single length of cord 26, the individual cord runs crossing over'each other within the thickened head 24 as shown at 21. The cord structure is then imbedded in rubber by vulcanization to comprise the integral sealing unit.

It is an important provision of the invention 5 that the cords in the walls run longitudinally of the seal I5 only. It will be seen that should the plunger be moved upwardly, for example, material is paid off from the cylinder ID on to the smaller diameter plunger I4 wherein the 10 cords are accordingly closer spaced than in the 'outer portion l8 as is clear from Fig. 2 and for the same reason the thickness of rubber on the inner portion 20 is greater than in the outer portion I8 in proportion to the different cir- 15 cumferences. It will be seen that the longitudinal cords in no way stiffen the structure against these changes in circumference and thickness as would any woven fabric or other reinforcements having circumferential elements. The bead I610 is clamped at assembly by a suitable cover 28 having a pressure connection 30.

It will be seen that when fluid pressure is applied beneath the cover 28, the load is taken in tension by the cords 26 which, being substantially non-stretchable as compared with the rubber, give the entire structure volumetric rigidity and permit high pressures to be carried despite the fact that the rubber itself is highly elastic and extensible. In other words, the rubso ber afiords complete fluid tightness while the cords carry the operating loads.

In the drawing, the spacing of the cords has been exaggerated. In practice, they will be so spaced as to be close together when on the con- 35 tracted portion 20. If, for example strands of cord like that which appears in Fig. 1 be used, the operating load will be distributed over 200 working portions of the cords. In this way, a structure capable of carrying very high pressures 4c; is afforded. At the same time, a non-porous elastic material and a tight clamp on the head It isall that is needed to insure zero leakage which cannot be affected by operating movement of the plunger and is quite independent 45 of the plunger flt.

The natural curvature assumed by the seals l5 and 3| due to their distortion from large to small diameter conforms to the shape which they will assume under fluid pressure which again 50 contributes to the objective of volumetric rigidity in the assembled device. If desired, the vulcanizing dies may take the form appropriate to Figs. 3 and 4 wherein the wall elements are molded as a straight taper extending from the u head to the bead, the sleeve so formed being turned partly inside out" before assembhr. This particular method will involve the bead section rotating relative to the end ring if this be made of wire or other rigid material, in which case it may be desirable to coat the metallic rings 25, 32 or 34 with some substance inhibiting adhesion of the cord and rubber thereto.

Figs. 4 and 5 show an alternative embodiment wherein a sealing sleeve 3| is provided with end rings 32 and 34 over which a cord 36 is reeved, the whole sleeve being impregnated with rubber, as shown. The large-sleeve end is held between thehousing l0 and the cover 28, while the small sleeve end is drawn inwardly within the larger sleeve end, the smaller end being clamped to the end of the plunger '14 by a cap 38 and a screw in.

The two arrangements operate in the same manner, the sleeves being diflerent only at that end which is engaged by the end of the plunger ll.

While I have described my invention in detail in its present preferred embodiment, it will be obvious to those skilled in the art, aiter understanding my invention, that various changes and modifications may be made therein without departing from the spirit or scope thereof. I aim in the appended claims to cover all such modifications and changes.

I claim as my invention:

1. A non-stretchable seal for piston and cylinder members comprising a flexible U section annulus contacting respective members, a closing head integral with the inner limb of the U and a bead integral with the outer limb oi. the U and cords extending through said seal between diametrically opposed points on said bead, said cords lying radially in said head and in the curved part 01 the seal between said limbs and lying longitudinally in said limbs.

2. As an article of manufacture, a tapered rubber sleeve closed at its smaller'end, a ring at the larger end, and cords, imbedded in the rubber, reeved from said ring longitudinally along one side 01 the sleeve, radially across the closed end and in overlapping relation with prior and successive runs of the cord, and longitudinally along the diametrically opposite side of the sleeve to said ring.

3. A diaphragm for sealing a plunger relative to a cylinder comprising a rubber conical trustum having a ring at its larger end, the irustum being integrally closed at its smaller end by rubber; and a single re-eniorcing cord reeved from said ring along a conical element, across the closed small end and back to the ring along a conical element substantially diametrically opposed to the first said element, around said ring and similarly back and forth along conical elements; so that cord runs lie adjacent to one another throughout the periphery oi the imstum, said cord runs lying one over the other at the closed end of the diaphragm. said cord, including all the runs thereof, being embedded in the rubber of the diaphragm.

4. As an article of manuiacture, a diaphragm comprising a conical irustum of rubber closed by the rubber at its smaller end, a metallic ring embedded in the rubber at its larger end; and a reinforcing cord, embedded throughout in the rubber, reeved back and iorth, around the ring, along a conical element 01 the irustuln, radially across the closed end, along a conical element substantially diametrically opposite to the first and around the ring; the successive cord runs in the aggregate forming longitudinally extending reinforcements, throughout the periphery of the irustum, between the ring and the closed end.

ROLAND CHILTON.

Referenced by
Citing PatentFiling datePublication dateApplicantTitle
US2460168 *Aug 14, 1944Jan 25, 1949Caserta MicheleMethod of making a diaphragm
US2478575 *Dec 9, 1944Aug 9, 1949Bendix Westinghouse AutomativcFluid pressure actuator
US2502256 *May 11, 1944Mar 28, 1950Harding Jr JohnFuel control valve
US2506208 *Feb 4, 1947May 2, 1950Gibson Clarence FSwitch
US2578730 *Jul 25, 1945Dec 18, 1951Ohmer CorpDiaphragm
US2638930 *Oct 25, 1946May 19, 1953Niles Bement Pond CoDiaphragm
US2642091 *Dec 19, 1947Jun 16, 1953Morin Alexandre HenriElastic diaphragm
US2657711 *Mar 23, 1948Nov 3, 1953Detroit Controls CorpActuating mechanism
US2694415 *Dec 23, 1950Nov 16, 1954Watts Regulator CoDiaphragm construction for thermostats or motors
US2725078 *Jun 27, 1951Nov 29, 1955Glancy Walter PFlexible liner assembly for a fluid pressure device
US2849026 *Dec 12, 1955Aug 26, 1958Taplin John FFlexible fluid sealing diaphragm
US2849977 *Mar 11, 1955Sep 2, 1958Goodyear Aircraft CorpMold for forming multicurved sheet metal tank sections
US2851565 *Oct 15, 1956Sep 9, 1958Pratt & Whitney Company IncPressure responsive switch
US2980571 *Aug 4, 1958Apr 18, 1961Us Rubber CoMethod of making a diaphragm for fluid spring
US2982310 *May 27, 1958May 2, 1961Reeves Bros IncMolded diaphragm of non-woven material
US2987915 *Dec 12, 1956Jun 13, 1961Honeywell Regulator CoFlow meter having axially movable orifice
US2991992 *Apr 11, 1960Jul 11, 1961Aeroquip CorpTime delay device
US3013920 *Mar 1, 1957Dec 19, 1961Us Rubber CoMethod of making a flexible diaphragm for use in fluid springs
US3030252 *Mar 1, 1957Apr 17, 1962Us Rubber CoMethods of making flexible diaphragms for use in fluid springs
US3057768 *Jan 7, 1957Oct 9, 1962Firestone Tire & Rubber CoMethod of forming an air spring of rubberized fabric plies
US3118389 *Aug 31, 1960Jan 21, 1964 Contaminant barrier for reciprocating pumps
US3185041 *Oct 15, 1962May 25, 1965Bacharach Ind Instr CompanyFilter gauge
US3203186 *Aug 25, 1960Aug 31, 1965Edwin J LukasForce transmitting system
US3241379 *Jun 12, 1962Mar 22, 1966Philips CorpDevice of the kind comprising rolling diaphragm seals between two relatively reciprocating coaxial elements
US3246580 *Jul 8, 1963Apr 19, 1966Paul HuskaRotary fluid displacement device
US3323423 *Mar 3, 1965Jun 6, 1967Mansfield Tire And Rubber CompReinforced flexible diaphragms
US3403603 *May 23, 1966Oct 1, 1968George & Angus & Company LtdTubular rolling diaphragms
US3408439 *Jan 24, 1967Oct 29, 1968Mansfield Tire And Rubber CompMethod for shaping reinforced flexible diaphragms
US3613518 *Dec 31, 1969Oct 19, 1971Autorol CorpDiaphragm actuator
US3650253 *Oct 3, 1969Mar 21, 1972Lucas Industries LtdVacuum operable units for use with ignition distributors
US3881400 *Feb 27, 1973May 6, 1975Lockheed Aircraft CorpFluidic operated valve actuator
US4086819 *May 19, 1975May 2, 1978Curtis Mitchell BrownleeRolling seal for a well having a rod-type pump
US4208060 *Jan 15, 1979Jun 17, 1980Bellofram CorporationSealed shaft
US4511126 *Mar 2, 1983Apr 16, 1985HutchinsonHydraulic membrane shock absorbers
US4544328 *Oct 5, 1982Oct 1, 1985The Coca-Cola CompanySold-out device for syrup pump
US4940399 *Dec 1, 1987Jul 10, 1990Pacesetter Infusion, Ltd.Piston cap and boot seal for a medication infusion system
US5138936 *Dec 28, 1990Aug 18, 1992Elie KentUnlimited amplitude rolling piston
DE1114275B *Feb 5, 1959Sep 28, 1961Volkswagenwerk AgKolbenkompressor mit einem stirnseitig mit einer eingespannten Rollmembran verbundenen Kolben
DE1227740B *Aug 14, 1961Oct 27, 1966Kurt Willutzki Dipl IngVerfahren zur Herstellung von Rollmembranen
DE3426983A1 *Jul 21, 1984Jun 5, 1986Neuhaus HermannWorking cylinder with rolling seal for the high-pressure and low-pressure range
DE8713271U1 *Oct 2, 1987Nov 19, 1987Sueddeutsche Kuehlerfabrik Julius Fr. Behr Gmbh & Co Kg, 7000 Stuttgart, DeTitle not available
DE10231075A1 *Jul 10, 2002Feb 19, 2004GKN Löbro GmbHVerfahren zum Herstellen eines Rollbalges
DE10231075B4 *Jul 10, 2002Sep 2, 2004Gkn Driveline Deutschland GmbhVerfahren zum Herstellen eines Rollbalges
EP0427460A1 *Nov 1, 1990May 15, 1991Yoshikazu KuzeSealing means for a thermostat
Classifications
U.S. Classification92/103.00R, 92/98.00R, 92/101, 267/64.27, 92/98.00D, 200/83.00B, 92/103.00F, 74/18.2, 92/99
International ClassificationF16J3/06, F16J3/00
Cooperative ClassificationF16J3/06
European ClassificationF16J3/06